1. Why do we Need a Mathematical Model? SAMSI/CRSC Undergraduate Workshop 2006 Moustapha Pemy

2. 1. The Reality, the experiment and the model. Let us denote by y true the true displacement of the beam, y data the data collected in the lab, and y the solution of the beam model.

3. 1. The Reality, the experiment and the model. Let us denote by y true the true displacement of the beam, y data the data collected in the lab, and y the solution of the beam model. Question: Is it always possible to find a mathematical formula to express y true as function of time?

4. 1.The Reality, the experiment and the model. 1.Let us denote by y true the true displacement of the beam, y data the data collected in the lab, and y the solution of the beam model. Question: Is it always possible to find a mathematical formula to express y true as function of time? How can we compare y true and y data ? How can we compare y true and y ? How can we compare y data and y ?

5. The Reality, the experiment and the model. 1. Answer: It is not always possible to find a mathematical expression of the reality. Due to measurement errors the data collected always differ from the reality.

6. The Reality, the experiment and the model. 1. Answer: It is not always possible to find a mathematical expression of the reality. Due to measurement errors the data collected always differ from the reality. In a mathematical model it is impossible to take into account all parameters of the experiment, for example in the beam model we do not take into account temperature of lab and any other gravitational forces that exist in the lab. This is why y true differs from y. As we have seen throughout this week, y data differs from y. This leads to the errors analysis in the model.

7. 2. The data and the black box Assume we do not have a model. Can we just with data collected in the CRSC lab derive a good understanding of the system?

8. 2.The data and the black box Assume we do not have a model. Can we just with data collected in the CRSC lab derive a good understanding of the system? Yes, just with data collected in CRSC lab we can interpolate the data using the least square approach or any other interpolation technique to derive functional relationship between the displacements of the beam and the times.

9. 2.The data and the black box Assume we do not have a model, and that we have interpolated the data from the Beam in the CRSC lab and obtained a functional relationship between the displacements and the times.

10. 2.The data and the black box Assume we do not have a model, and that we have interpolated the data from the Beam in the CRSC lab and obtained a functional relationship between the displacements and the times. Can we use this functional relationship to study a larger beam?

11. 2.The data and the black box Assume we do not have a model, and that we have interpolate the data from the Beam in the CRSC lab and obtain a functional relationship between the displacements and the times. Can we use this functional relationship to study a larger beam? No, without a model we cannot use the functional relationship of a smaller beam to study a larger beam.

12. 3. Interdependence of the model and the data Is it possible, just with experiments to obtain all necessary or desirable data of a physical system?

13. 3. Interdependence of the model and the data Is it possible, just with experiments to obtain all necessary or desirable data of a physical system? No, there are certain data that are not observable, we cannot obtain them just with experiments. In fact, we need experiments and models in order to filter out unobservable data.

14. 3. Interdependence of the model and the data Can we fit the model without experiments?

15. 3. Interdependence of the model and the data Can we fit the model without experiments? No, in order to calibrate and validate the model we need experiments

16. 3. Interdependence of the model and the data Why do scientists use both models and observed data?

17. 3. Interdependence of the model and the data Why do scientists use both models and observed data? Control and design Navigation (Space shuttles, Satellites, Rockets) Predictions and Forecasting etc…

18. 4. Models without data Give examples from science and industry where it is extremely difficult to collect data, and scientists mainly rely on mathematical models?

19. 4. Models without data Give examples from science and industry where it is extremely difficult to collect data, and scientists mainly rely on mathematical models. Astrophysics: due to the large scale.

20. 4. Models without data Give examples from science and industry where it is extremely difficult to collect data, and scientists mainly rely on mathematical models. Astrophysics: due to the large scale. Nanotechnology, quantum physics (very small scale).

21. 4. Models without data Give examples from science and industry where it is extremely difficult to collect data, and scientists mainly rely on mathematical models. Astrophysics: due to the large scale. Nanotechnology, quantum physics (very small scale). The design and the testing of nuclear weapons.

22. 4. Models without data Give examples from science and industry where it is extremely difficult to collect data, and scientists mainly rely on mathematical models. Astrophysics: due to the large scale. Nanotechnology, quantum physics (very small scale). The design and the testing of nuclear weapons. In Biomedical sciences, certain measurements in vivo can be destructive

23. 4. Models without data Give examples from science and industry where it is extremely difficult to collect data, and scientists mainly rely on mathematical models. Astrophysics: due to the large scale. Nanotechnology, quantum physics (very small scale). The design and the testing of nuclear weapons. In Biomedical sciences, certain measurements in vivo can be destructive In the design and the development of jet engines and big airplanes like the Airbus A380 etc…